Television receiving system



May 16, 1950 J. D. REID 2,507,995

TELEVISION RECEIVING SYSTEM Filed Nov. 12, 1947 5 sheets-sheet 1 ,Jknllflei May 16, 1950 J. D. REID 2,507,995

TELEVISION RECEIVING SYSTEM Filed Nov. l2, 1947 5 Sheets-Sheet 2 E 74 7376 75 75 855* f8 'ua w16/ o 58 LQ/ smllmlm 5 ,ro kn ZZZZeiJ May 16, 1950 Filed Nov. l2, 1947 J. D. REID' TELEVISION RECEIVING SYSTEM 5 Sheets-Sheet 5 lull- May 16, 1950 J. D. REID 2,507,995

TELEVISION RECEIVING 'SYSTEM Filed Nov. l2, 1947 5 Sheets-Sheet 4 gnam/MM fa/m1139150?.

May 16, 1950 J, D. REID TELEVISION RECEIVING SYSTEM Filed Nov. 12. 1947 5 Sheets-Sheet 5 John D. Reaal.

Patented May 16, 19.540

UNITED S TTtES RT 1 The present invention relates '.:generally tto f'ele'ctifcmiagnetic f'ffwave ...'signal-` lreceivers, particularlyito andHFireceivers :and-specifically to television receivers of the superhetenodyne 'tion comprisc-:slanovel television :receiver featuringl ffch'a'rnfiel5 Iselectorfuriits. Each :ffunit: fis ifdemountable and comprises tunedfRfFxantenna- `input' and-ilocal oscillator @circuitsv optimized to Arender '-thereceiver responsive tossignals 'Within g-a'f specicfone- ;onlyi1of-.a -pluralityiof vtelevision vchannels. 'Eachireceiver 'requiresI only .a limited 'inivirrb'er #of :units to coverftransmitters .fin lservice inf its iarea.

Il.'.Iel'evision llreceivers of fthe -ssuper-,heterod-yne f,

type generally 'comprise an :antenna :system for inter'c'epting fifele'ctromagnetic 'wave -.-.energ.y, .1 ,a Tfradiofireqziencysignalstranslating oraamplifying sys'temforlapplyingf the.sig-na'lenergyV :from'a desired transmitting station cto... a' :frequency: .converter r circuitconsisting ofa loc al .oscillatiomgenierating fsys'te'mfan'd.- aimixerfor flrste'detectorifor beating' fthe .ilocal oscillations; and i the yreceived signals ltogetheruto ioonvert-tthe;latteninto :inter- :mediate-frequencyiisignals, a1 picture intermedifatesfrequenoy'famplier `system forxamplifyin'g the I. F. signals carrying the picturelinformation, v'terminated' in .a-fsecoxid-id'etector or -rd`emodulator forialo'stractingv orf deriving. :from: the :amplified I. F. signals the modulation components/ofthe wreceived -=picture signals' ftcon'sistingzef eline; or horizontal ipulse's which f cause successive flineseto *be `ls'canned,f:field oriverticalzpulses :which .rcause -repetition .of vthe .f1ine.,:scanning fsequence f fand ".videosignals .which .'cause'developmentrzoffithe 35 =reproduced'picture)f, circuits r vfon :separating zthe 'horizontal `land L.vertical .f.:pulses': from1-=thevvideo signals and from each other, azvicleoV .frequency amplifying system for amplifying,lthezlvideolsigmals, apicture tube :responsive to Vthe vide'ocsigmals-LI for developing f-.the'r picture el'ements',1.andf a pair loflsa-wstooth wave 2 generatorsnzesponsive :to Athehorizontal and verticallpulsesfior-fcontroliing "the position' and-'sequencefof -the "..pioture .ele-

Iments, asoundintermediate-frequency.amplifier ssy'stem, a .sound/.detector ='or..'discriminator.l1ffor .abstracting or y\derivingSironi:the f amplified I'isi'gnals "@the.rmodulationf componentes-.fof the :sound i I. F. signals; an.- audio voltage amplifier -followedf .by y an 'f audio. powera .amplier; ffwhichliin lturn feeds a loudspeaker. :Theftpresent inven- -tion 1 relates to that f'portionofv a atelevision vire- 'lceiver' @which is f.':electricallyrpositioned e between @the antennas-systemandfthef frequency: converter.

portionvcomprises f elements hereinafterfcol- ST2 lectively referred to as the -fflsaF.inputsystem.f :'Tfhe .L-basic functions ,which.,.should .be .perzioimedfhy the-Bali?. finput system are:

First .in response-'to ythe willpi ...the operator, to select modulated carrier wave signa1sv,.in..a desiredfchannel;.anditofdiscriminate,againstfsigina-ls :ingalliother channels;

A:'.Seconi to .convert -those `:signals .finto inter mediate-frequency signals and with predeterim A.mined,1. '.:F.';.:carrier. :frequencies for. the `fpictu're and sound I. Refrequencies;

Thil-id; ,ato f pass .the ksignal .energy .to.;.the. iinter- .-mediateffrequency.amplifier with amaximumsof Lgain.ami-:a minimumoffdistortion.

All of these functions shouldfiaeperformednn ua @commercially ep1:actical mannen without .-.lim-

posing undue costs and operating complexities on the operator.

The..diesign of an. R. F.. .input for televsiomre- 26 -ceiuersposes .aweryiermidable-,problem- -Inkthe .25 @highest 6219-2l-.jmegacyclew one.v ..hundred nals and discrimination. @against v.undesired .i Sig- .nals. .,-It., isE impossible, .to.provide an! R. F. .input system continuously .tunable `throughoutthis span and-f. at. `tha-same y.time tollfprovide-optirnum conditions for the .reception-:of signals1 .in each channel. f AInt continuously :tunable R. F. nput rsystemmcperformance; imgeach channels-.is 1m- :pairedjnmrderzthatzsignals in.1al-lr.channels.xnay SheI received Furthermore, theccorrectperifm- 40 -sanvcei OfitheM-soundzzand; video lI;1li'.circreitet-ami 'dtectorserequires that the l? Ewcarriersfrequen- -"cies" shouldJl be44 maintainedl with considerable iaccuracy, a requirement EJ'it -v-'becomes' increasingly idii'cult' vto 'comply' with" a'sithe'l R1' *F.l frequencies wis 'to "avoid this -'serious' iiiiiitationof" priorart systems and. ,provide v an R. F. input,I systenr'in Which,.signals l.from any one ,of apluialijy lr0f .availablechannels may he -selec-ted ...underwoiitimumconditions .for eachhchannl.

y Marions-proposals forwavoidingnthesel.limita- Ctionswhave been.madewithsresultsyaryingf from mediocre performance to failure, each .offsuch i,55 ,proposalsbeing.characterizedtbyne .onmor of the following non-exhaustive list of disadvantages:

First, the peril of complete obsolescence if eX- isting assigned frequency channels are changed;

Second, lack of provisions for additional channels if such channels should be assigned;

Third, redundant provisions for channels other than those available in the area where each receiver is to be used;

Fourth, lack of flexibility of antenna arrangements;

Fifth, untuned R. F. stages and resultant lack of sensitivity gain, freedom from interference. and loss in signal-to-noise ratio;

Sixth, poor antenna line match;

Seventh, exposed components, susceptible to humidity changes and other factors causing poor oscillator frequency stability;

Eigth, switching in oscillator frequency-determining circuits, with resultant aggravation of frequency instability;

Ninth, the need for relatively long leads in the frequency-determining circuits, resulting in low fixed capacitances and therefore poor frequency stability;

Tenth, the necessity of frequent retuning;

Eleventh, the necessity of fine adjustments and receiver alignment by service personnel in the field;

' Twelfth, undue complexity resulting in excessive costs and service diilculties.

Itis believed that the present invention provides a solution to this problem and avoids the disadvantage and limitations attendant upon the prior art systems. l

The basic objects of the invention are to provide:

First, a novel channel selector unit;

Second, a novel dual channel selector unit;

Third, a system of standardized channel selector units;

Fourth, a television receiver having a flexible arrangement of one or more channel selector units, such units being provided in each case to correspond to the television stations in service in the vicinity of the receiver;

Fifth, a television receiver having a plurality Ofsuch channel selector units and a switching systemv for readily and easily selecting the signals from any one of the television transmitting stations in service in its area;

'Y Sixth, a television receiver having one or more selector units each specially designed, tailored and loptimizedfor its respective television channel, whereby maximum gain, selectivity, fidelity, efficiency and sensitivity may be achieved;

Seventh, a television receiver having readily replaceable channel selector units, whereby when the receiver is moved from an area served by one group to another area served by another group of transmitter stations, a different set of chanlnel selector units may be substituted for those previously installed in the receiver;

Eighth, a television receiver having facilities for the addition of channel selector units for additional channels that may become available in the future;

Ninth, a television receiver having replaceable channel selector units, the cost of which is minor compared to the total cost of the receiver, so that a change in frequency allocations would lnvolve low-cost replacement of selector units but not high-cost replacement of the receiver as a Whole; I

' Tenth, a television receiver having facilities for 4 ready conversion to receive color television signals in the ultra-high-frequency television band, should color television broadcasting service with standards compatible with present black and white television standards, or standard signals become available in this band;

Eleventh, a television receiver having channel selector units so constructed and arranged and of such high frequency stability that manual Vernier tuning is eliminated, whereby to avoid vthe disadvantages and limitations attendant upon retuning during a program;

Twelfth, a television receiver having such construction and operation that no radio-frequency service alignment equipment or operations are required;

Thirteenth, a novel selector unit having such arrangement that when a local oscillator circuit for a particular channel is selected as by switching, the proper selective antenna input circuit is simultaneously selected;

Fourteenth, a television receiver which does not require the dependent alignments of several channels;

Fifteenth, a receiver which avoids the complications of manufacturing, testing, servicing, tuning, aligning and adjusting p rior art multi-channel tuning systems.

Ancillary objectives of the invention are to provide: a channel selector unit having a hermetically sealed construction and requiring no oscillator circuit switching, whereby great frequency stability is achieved; a television receiver having channel selector units each readily replaceable and demountable, whereby service and repair are facilitated and simpliiied; a novel channel selector unit which is unusually well shielded and balanced; a channel selector unit having such construction that local oscillator radiation is minimized; a channel selector unit which is simple to manufacture, the channel selector units and main chassis being separately made; a channel selector unit which permits local interference conditions to be overcome by builtin filters or traps and without extra switches; a novel channel selector unit adapted for flexible antenna provisions.

Still another subordinate object of the invention is to achieve maximum utilization of circuit components.

For a better understanding of the present invention, together with other and further advantages, capabilities and objects thereof, reference is made to the following description of the accompanying drawings, in which there are shown pertinent portions of an illustrative television receiver having channel selector units in accord ance with the invention.

In the drawings:

Figs. 1 and 2 are, respectively, top and front (partly in section) views, including the covers of the novel channel selector unit having separate circuits for two channels; Figs. 3, 4, 5, 6, 7 and 8 are, respectively, top, front, left side, rear, right side and bottom views of the channel selector unit, the covers being removed; Fig. 9 is a cir.- cuit diagram symbolically showing the two sets of electrical circuit elements included in the two-channel selector unit illustrated in Figs. 1 8; Fig. 10 shows certain portions of a television receiver in accordance with the invention, beginning with the antenna and ending with the frequency converter stage, including four sockets on which four plug-in channel selector units as shown in Figs. 1-9 may be mounted and ganged switch sections'v constituting. a', charmer selector: svli'tbl-iwhei'ebyeny one@of-eighttelevisibnclianlv nelfniay? be selected; atlthe: will! of thetope'rator; Fi'gifilgf ian alternativas-nooit diagram of as'eti otelectrical circuit elementslsuitable'.. for: inclu-1 siominfrthe Fig. 1f embodiment; and Iigi. l2H is'k a'v perspective ,view showing a` channel selector' unit being plugged `into a socket-onv the receivi'er"chassis.

A complete appreciation of. thepresenty invent-vv tion'. involvesa consideration'of .the television'ffree'- qencyi channels presently: assigned.: by the'Eedf'e eral Communications Commission as Wel-llasfprese ent and anticipated. marketing conditions in; ther television field.

'L'.her'e. are now thirteen television channels-:individually numbered lto'l; inclusive. Adjacent noni-spaced channels vare not .i assignedrin any oneV metropolitan district. No:V change inthisassign-v meritpolicyy is reasonably to be anticipated. Channel'l not beingfassigned to any of'thef'prinfcipal metropolitan centers, it follows tha't not niore than seven channels can=or Willbeassigned in. any! one community. In many communities only; onev or two channels are or will be' available. Iir-'is'fairly estimatedthat by the year 19.54fthe' average number of channels availablein alltele-f visi'oneserviced areas throughouttheUnited States Willtbe four, that atleast 38% of the television receiver markets" will be served byl not. more; than one or two channels, and that not` more thanl 34%- of: such markets can potentially: be served" .by sevenv channels. Itwill be seen thatl it is highly desirable to provide a flexible receiver constriic'tion,y adapted tcvbe optimizedN for substantially onlyV those channels available in: its1 location,l whether the number be one, four or selven,.rather than a universal receiver constructibn' havingl redundant circuit arrangements permitting it potentially to receive signals". from six-v t twelve non-available channels, which circuit varrangements preclude optimum design for the: available channels.

.It is highly desirableto tailor each receiver' in accordance With the television channels avail*- able in the area wherein it is'installed.` Thisr'equireient conflicts with the practical require'- ment's of mass manufacturing of televisionv re cei've'rs, which' dictate uniformity in chassisxunits'; produced. The invention'A reconciles. these conflicting requirements by providing: channel selec-'1 tor sub1-assemblies demountable frorr'r the chas-` sis. It has been found: that one ormore: units` chosen froml three single channel selectors- -for channels 1, l2, 13 and' ve dual-channel selecnf trsi foi-- channels 2-4, 3 5, 5 7, 8-10' andr'fQ-ll will cover all channels in all localities whereirr television service is presently available or pro'- jected. In New York, New York, for example, three dual-channel selectorsr for channels 2 4.. 51T, 9-11 and one single channel selector for channel 13 will afford complete channel cover*- ag; In Hartford, Connecticut, one dual-channel selector' for channels 8 1() will provide complete` coverage. The signicance of these facts isthat a New' York customer can purchase four channel selectors and can obtain optimum reception over alll prescrit and contemplated channels in hisiare'a, saving they cost of redundant circuit arrangements which potentially provide for reception of non'- available channels. A Hartford customer will require only one dual-channel selector uni-t', for example'. A Scranton, Pennsylvania, customer would need one single-channel selector unit for' cnannei r and a Soesterunit for cri-armer 1i, forv turedinstalled.. removed or4 serviced essuie-ass.

sembliesb When a` receiverl isiinovedtofazdiffen entl area, one or more channel selectorsimayfbe substitutedrfbrf those. previously.installed:4 If ferent frequency. assignmentsV areniade; diierent; channelz selector units for. the different. channels?-r maybe-provided.

If. repair' or replacement. of a. channel:Y selector.` unit becomesnecessary,.thereceiver need noti ber delivered to a repair agency..` Notuning-is: rei-*f quired' since the operator simplyf switches in*A the desired selector and receives.y theY progra-rn. fronti any; desired; station in his.A area under optimum-.1 conditions: The selector unitsif are hermeticallyef sealed' to" assuref frequency stability andv Wella shielded to minimize: oscillator-radiation; Flexif ble antenna arrangements may be made. Each@ receiver: is' specially; tailored for' its; television service area.l Bylstartin'g with one? channel selec*- ton unit. andfadding others as additional channels; become: available in his area, the consumer mayf buildup-his recel-veras required The invention.. inishort, achieves theladvantagesf of trulytailored# television along with those of standardiZedkma-nu fact-uring.

Referring now specifically.y toFigs. l-8, thereis`vl shown an illustrative-formA of dual.channelxselec--fl tor.` unit inaccordance with the invention. Figs.. 9. andl1- show alternative.v circuit diagramsv suite ablafor incorporationin the Fig. 1-8 embodiment. Fig. 10 is a circuit diagram showing the relationeship between. thea four channel selectorl unit mounting sockets, their gangedfsection channelA selector switch, and the. antenna. system and fre-- quencyY converter of a television receiver. The construction. and operation-of those. stages in cast-f` cade Withand. following the converter unit aref not embraced within the present invention andf` are so wellknown tothosefskilled in the art that they needfnotfbe shownor described herein.

Referring. first to Fig. 9,. the dualfchannelise lector unit. comprises: amounting generally indi-- cated by the` numeral, I5; two supply terminals.. ISa, |6b adapted. to be selectively coupled tov a suitablespace-current source |B (Fig. l0) by sec tion Hf of a ganged channel selectorv switch- IJ. tosupply plate potential to-a desired. one of oscillator tubesections |180., lb (Fig. 9); two pairsof. input terminals I9a, Zlla and l.9b,.2llb adapted to beselectively coupled toantennaleads 2 I, 22. (Fig- 1.0) bysections. [la and Ilb of channel. selector switch` Il. to apply received. signals. to a desired one` of R. F. input antenna transformer circuits 23a, 23h; two pairsV of output terminalsv 24a,k 25a and 25h, 24h, adapted to be selectively coupledl to the pair o'f control electrodes 2T, 26 of frequency converter tube 2'8 (Fig. l0?)v by sectionsV lle and' l'rl" of channel selector switch I1 to supply to. the, frequency converter received signals in a desired channel and local oscillations of appropriate fre--V quency; a common terminal 29 adaptedj to' be grounded' through section llfc of the channel se.-

7 lector switch in order to ground the cath-ode of converter tube 2-6 at a point near tol the' channel selectorc'ircuit in operation; a filament supply terminal 30;Y and two local oscillator circuits 3Ia and 3Ib, one for each channel; and associated vviring and mechanical structures shown in Figs.

The television receiving system illustrated in Fig. embraces provisions for four dual-channel selector units. Accordingly, it includes four sockets symbolically shown at 35, 36, 31 and 38 into which the channel selector units are plugged. The connections and details of socket 36 are the same as those of sockets 35, 31 and 38, so that socket 36 is alone described in detail herein. It includes an octal arrangement of conductive connector elements Ib, o', 24h', 29', 36', 25a', 24a', I6a, respectively, complementary to and adapted to receive plug terminals I 6b, 25h, 24h, 29, 38, 25a, 24a, I6a, and a quadrangular arrangement of connector elements I9a, I9b', 20h', 20a', respectively, complementary to and adapted to receive plug terminals I9a, ISD, 20h, 28a of the channel selector unit.

Switch section I1a has a rotary contact connected to antenna lead 2| and eight fixed contacts, two of which are connected to terminals I9a, I9b of socket 36, as shown, and the remaining three pairs of which are connected to corresponding terminals (not shown) on sockets D 31, and 38.

Switch section Ilo has a rotary contact, connected to antenna lead 22, and eight fixed contacts, two of which are connected to terminals 28a', 2Gb', of socket 36, as shown, and the remaining three pairs of which are connected to corresponding terminals (not shown) on sockets 31, 35 and 38.

Switch section I1f has a rotary contact, connected to the plate supply -I- B, and eight xed contacts, two of which are connected` to terminals Ilia', Ib', as shown, and the remaining three pairs vof which are connected to corresponding terminals (not shown) on sockets 31, 35 and 38.

lSwitch section I1e has a rotary contact, connected to the control electrode 21 of converter tube 28, and eight fixed contacts, two of which are connected to terminals 24a', 25h', as shown, and three pairs of which are connected to corresponding terminals (not shown) ony sockets 31, 35 and 38.

Switch section I'id has a. rotary contact connected to the control electrode 26 of tube 28, and eight xed contacts, two of which are connected to terminals 25a and 23o', as shown, and three pairs of which `are connected to corresponding terminals (not shown) `on sockets 31, 35 and 38.

Switch section 'Ic has a rotary contact, connected to the cathodes of converter tube 28, and nine fixed contacts. One interconnected pair of these contacts is connected to terminal 29', and the three other interconnected pairs are connected to corresponding terminals (not shown) on sockets 31, 35 and 38. The remaining contact is connected to the rotary contact. The rotary contact has a sufcient arcuate length to span two contacts. The ren-raining contact is connected to the rotary contact. Since the arcuate length of the rotary contact is made sufficient to span two contacts, the addition of the ninth terlminal will insure that a cathode to ground connection for the tube 28 always exists. This is desirable to avoid noise during switching.

flfhe sectionsofl the switch Ilrare ganged to 8 operate in unison by a suitable expedient indie cated by the dashed lines 42 (Fig. 10).

I1 constitutes means for selectively coupling either of the two channel arrangementsin any of the four channel selector sub-assemblies to the common circuit means comprising the con, verter tube 28 and all succeeding stages (not shown) in cascade with the converter stage. As shown in Fig. 10 one channel (see left side of Fig. 9) of the channel selector unit mounted `in socket 36 has been selected. The other channel of this unit may be selected by turning switch I1 The basic function of sockets and the switch I1 is to intercouple or electrically interpose any one of the eight channel-selective systems between the antenna and the rst converter stage. basic function involves four sub-functions:

First, coupling the anode voltage supply to the proper oscillator tube anode, as by the circuit including elements +B, I1f, I6a, or ISb, IEa or I6b, anode of I8a, or I8b;

Second, grounding the cathode of converter tube 28 near the proper channel, as by the circuit including elements I1c, ground, 29', 29.

Third, coupling the proper antenna input transformer secondary to the converter tube input circuit, as by the pair of circuits 24a, 24a', I1e, control grid 21 and 25a, 25a', I 1d, control grid 26 or the pair of circuits 24h, 24h', I1d, control grid 26 and 25h, 25h', I'Ie, control grid 21;

Fourth, coupling the proper antenna input transformer to the wave intercepting system, as by the pair of circuits 2I, I1a, Isa', I'1b, 20a', 28a or the pair of circuits 2l, Il'a, I9b, I9b, and 22, I1b, 20h', 20h.

Referring now specifically to Fig. 9, a suitable circuit for the dual-channel selector units is shown. A single channel selector unit comprises the mounting I5, a fixed-tuned local oscillator circuit generally indicated at 39a, a fixed-tuned antenna input circuit generally indicated at 23a, together with terminals I9a, 29a, I6a, 24a, 25a, 29, 38 and associated wiring. It has been found that the dual-channel type has unique manufacturing advantages and can be constructedat a cost little in excess of the cost of a single channel unit. There is also provided in the dual-channel type, another R. F. input comprising a xedtuned antenna input circuit 23h, a fixed-tuned local oscillator circuit 3Ib, together with terminals I9b, 2Gb, I6b, 25h and 24h. Terminals 29 and 36 are common to both channels. cathodes of tube I8, one lament lead and mounting I5 are grounded. Filament terminal 38 is connected to a suitable A potential source (Fig. 10, not shown). Since the channels are generally similar and differ only in circuit dimensions, the following description of Fig. 9 is conned to the channel including antenna input transformer circuit 23a and local oscillator circuit 3 I a.

The antenna transformer circuit 23a comprises minals I9a, 20a and comprising two inductorVK Switch This I9a and 22,

The

-mrtions 4ta, fara, ateppeaet ,their closed-enum ,znductor 4a-to fmaitch a 75 rohm 'antenna line.

@primary fis #tuned rby a fparallel icombination of trimmer icapazcitorfftilu iandfxedfcapacitor 50a fshunted :across the open end 1- of inductors A611, 41a. Theresistortllais lafstatic leak prefventinga voltage build-.upin the antenna in the .case where a rseparate antenna -is rconnected directly to the: converter unit.

Transformer circuit :33a 1 also includes Vassecion'dary `Sla, electrostatically shielded from lthe rprimary; by-a shield 52a,v providedy furthe purpose of reducing push-push radiation of '-localoscillatQnsignals, resulting 'fromelectrostatic coupling "'fliom thesecondary into theprimary. 1Further .fto..avo id oscillator signal -currents conducted-by shields for chassis, `the oscillator coupling coil '50a-fof ,the-,channel vbeing used-and the converter xc-athodes.may be v'grounded-@at a common-point je29,;29'{(Fig.-10)

Secondary -.5 l a V is I coupled to. output terminals 24111, 25a, thereby applying the received signalsto those terminalswith :a stepped-up voltage.

A triode section Ia .of an indirectly-heated- .cathode-:twin triode. L8 is ,employed as an .oscillator `tube. Anode potential available .at terminal Ilia-vvhen.thischannelvis chosen and is applied ,tocthefanodO-triode. I'8a through plate resistor $5311, fthe rtube ebeing .arranged .to employ shuntfeed in its y.plate .,circuit .The oscillator vis `a Qolpitts type comprising agparallel-.resonant tank circuit, includingan .inductor 55a. ancla vdouble- ,endedcapacitor 56a, coupling `the plate and .grid circuits of tube lSa. v"The capacitor 56a is so varranged as to provide capacitanceibetween the grid circuit, andground vand capacitance between vthe plate circuitand ground, having oneiterminal grounded or -eiectivelyconnected 'to the cathode of .tube .[8'a. .Theinstantaneous voltages .at the ends of the parallel-resonant circuit are vopposite -inpolarity with respect .to the cathode land inthe properphase to. sustain oscillation. A grid resistor 51a is connected. between ,grid and ground of..tube..| 8a. .'.A blocking capacitora is connected between .,the z.tank circuit, and .the grid, to isolate the'gridlfromthe D. C. platepotential. ACOlptts oscillator ...circuit `is per se Wellknown tolthose skilled .in lthe art, and many descriptionsof .its construction and` operation may be .foundin .the literature, forV example, in

AppliedElectronics, M.,I. T. Staff,.p.61"7., .1943, John Wiley .& Sons,.Inc., New York,.NeW York;

-Theory .andApplication-s of Electron Tubes, Reichp. ,39.1, 1944, McGraw-Hill, New York-.New York;

:Radio Engineering, Terman, p..f34 9, p. 359,.,1937, McGraw-.Hill

Radio. AmateursI-Iandbook, p. 180, 1.9.47, American lRadioRelayLeague, Inc., West Hartford, Conn.

stated above, the vamplified sreceived. signals are .appliedto theegrids Yof Aconverter. tube `28 (Fig. 10) `through terminals .24ct, -2.5a;(Fig..19). .The local. oscillations-.are also injected Vinto .the -fgridscfg-the comenten. .being appliedV to :terminals 24a, a, and .29in .balanced relation withrespect V4to grounded terminal f2.9, foy` coilk .-5911, electromagnetically coupled to inductor 55a, and a capacity divider fcomprising capacitora l a.. andfadjustable oamacitor-lf2aA .This capacity,` divider is fshunted across-.antenna 'input :transformer secondary 5 la.. One terminal of coupllng-coileais oonnectedeto the )junction of serlesfarraneed -eapaciters e la, aeand the -:other f'terminal fisconneeted :to terf l'minale29.

,"Af'trimmer capacitor.v 63ais shunted `across the antenna input transformer -secondary Sla yfor tuning that secondary.

Chassis "ground Acurrents and oscillator radiationmaybe reduced by obtaining the local oscil.-

lator vol-tagefrom thetankcircuit 155m 56a by .means .-'of a coupling -coil 69a, rather` than emryplayin-gatapon-the-coil 55a.. l Y ",Therlaments-'of tube'lfare connected-infseries .between .the grounded mounting member I 5 .and

terminal ll.

,fAsfstatedf-.above theconstruction and operation, ofthe-votherchannel (Fig. 9) including-oscillator tube section tb, oscillator-"clircuit-SIb,..an tem-ia .input circuit 2 3b .and ,terminals-|91), Zlib, 29, 39, 2417,.-,21512 and:lBb,arergenerally'thesame .asthat ofithe channel ,just-described in detail',

dilering only in A:constants and dimensions .pro- .vided ineorder togenerate/.local ...oscillations of `a different frequency and Ito optimize the ,voltage amplification gof'freceive'd vsignals riny a different channel. Y Reference ,is now ,made -to the 7novel ,charme selector unit illustrated v'in Figs. .1-8. `Thecirfcuitrelementssymbolically shoWninfEgr-Q bear :the-samefreference numerals as the-identicahoircuitelements illustrated, in Figs. :1=8.

The Iunit is provided with a 'metallic mounting or -frame rI5 `which lhas ,var-circular Ybase 1:0 .apertured Iin two places to accommodate :conductors conneetedfto v`plug-.terminals ofthegroups 49a, -l;9b, 29a, 20h fand 16a, 161i, 1.24ct, v24h, .-Zq., 2,51), r2,9, 30r (Fig...8) The latter-group are simple point Yplug k:elements (Figs. =5-7). The former group l1-ave :removable ,jacket Y plug nuts fs crewed on toshortfscrews, 'for antenna flexfibi-litypurf poses explained,-disclosed.and claimed infthe-copending patent application of vlI-Iarland lA. eBass, entitlted Antennafconnector system,` Serial-No. '785;245Yled inthe United States Patent vOllee November .-12, ,f1947,eandasSgnedfto--the same 'ase signee K-as the present inventiorrand application,y 'Ilh'isqarrangement of plug ,j ackets is lclaimed rin thatvapplicai'fion-v and isnot lspeciicallgy'a partA of the-present. invention. Secured-)to the basef'asby screws (Fig. 8) is fan :insulating strip 'H -on= which theseftwo groupsoffplugs-,are mounted.

The mounting l5 also includes a ceilingimermber :.ovrihorizontal Idivider 12" having an upturned annularflange. Secured -on top of the ceiling; `for example, bysolderingyis a metallicsupnoltt I73de!"thesocket 'lfof tubeI I8. Thersupport '1;3 has a metallic rearwardly extending central-fin .115, rsuitably cut out "to provide space for "a v'tube socket insulation :aterminalstrip and terminals'. Secured 'to :the metallic support f1.3 :and '.its Tiin '.15 -is a generally semi-circular member :having Wings 5&9 4and f'80 `(Fig. I3). These rWings support 'adjustably mounted magnetioslugs 8l, 582 which proi'ect intofoscillator tank circuit coils 55a, and 55h respectivelm for tuning the -localofscillator rcircuits 3 lafand -3 tbrespectively. Shunted across :coila lis/aai pair. of series-arranged `tankcapacitances .comprisinga ,grounded plate 85a, ta-plate 86a-.connectedby a;.istrapre2a to an anode iterminal (No vofftube land a plate .alcone nected through a: strap-:89a and ai blocking capaci` I.tor-fzoa toa-gridterminal (No. 1) oftube t8. Grid resistor -Elaris mounted :between the last-men- ;tionedfgrid 1terminal and, grounded 1:11115. The

'plate fso.cket terminal =is yconnectedfto `.the 'F1-TB suitably insulated conductor 9|. The cathode (No. 4) and the other side of the lament (terminal No. 7) are grounded to wing 80 andn 15, respectively. The socket base and shield 14 are also grounded to fm 15. The` foregoing description of the mechanical details of the oseillator section 3Ia makes apparent the construction of the oscillator section 3Ib, comprising slug 92', Vtank coil 55a, tank circuit capacitor 56h, blocking capacitor 58h, grid resistor 51h, and the grid (No. 8), ground side of filament (No. 1), anode (No. 6), cathode (No. 4), (No. 5 grounded towing 19), and high side of filament (No. 2) terminals of tube I8. v

A type r(F8 twin triode tube (8 BW base) is suitable for use as the oscillator tube.

The description now proceeds to the antenna input transformer sections of the channel selector unit. As best shown in Figs. 4, and '7, two shielding compartments are provided between ceiling 12 and base 19 by partitions 95, 91 and 98 disposed in perpendicularity therebetween. These compartments preferably extend rearwardly slightly beyond the plug members 29a, 29h. The rear walls 99, |90 of the components disposed transversely of partitions 96, 91 and 98 are apertured to receive the ends of insulating sleeves IOIa, I02a, and IOIb, |025 respectively. Partition 91 extends substantially across the diameters of members 12 and 19, as shown lin Figs. 5 and 1. Two other shielding compartments are provided at the rear by a generally arcuate partition member |05, extending transversely of wall 91, and two wall members |96 and |01." The construction of these partitions and compartments is such as not only to provide a mounting for the various compartments but also to shield them. It will be noted that member 12 shields the two oscillator sections from the an'- tenna input transformer sections. Secured to the base member as by the screw and nut arrangement shown, is an insulating spacer |99 (Fig. 5) at the top of which there is mounted a strip of rigid insulation |09, extending transversely of spacer |08 to wall 91. On the other side of wall 91, there are similarly provided insulating spacer I I9 and insulatingY strip I II (Fig. 7)

The antenna input systems are generally similar, Ydiffering only in circuit dimensions, so that f the following description is confined to that one of those sections which is generally designated in Fig. 9 as 23a. Y Y

Concentrically disposed within and throughout the length of sleeve IOIa (Figs. 4 and 7.) is provided atubular shield member II2a. Similarly disposed within sleeve I92a is a tubular shield |I3a. The shield 52a (Fig. 9) includes members II2a, I|3a. Concentrically disposed within the shieldsV II2a, II3c, are insulating sleeves |I4a, II5a. The primary 96a, 41a of the antenna transformer is a hair pin having its two sections disposed within sleeves I Illa, I|5a, and shielded by elements II2a, I3a, respectively. Elements I9Ia, I92a, II2a, II3a, II4a, II5a, extend from and project through rear wall 99 to the front wall deiined by partition member |06, which is apertured to receive |I2a, II3a, IIa, II5a. Shield 52a isY grounded by conductively securing members I I2a, I |3a to wall |96. The primary is tuned by a. xed capacitor 59a and a variable capacitor 49a, shunted across its open end and mounted in theucompartment deiined by numbers |95, |96. This primary is shunted by a xed capacitor 59a, and aligned at its open end with a trimmer 49a,

12 mounted in the compartment dened by members |95, |99. The coil 98a between the hair pins 46a, 41a is mounted within the partition dened by wall members 91 and 98 (Fig. 4). l

The primary coil 49a, 41a, 48a may be made of continuous lengths of wire onto which conductors I 2| a and |22a are tapped, thereby dividing the hair pin 46a, 91a, from the coil 48a. Conductors I2Ia and I22a are terminated in terminals |9a, 29a, respectively.

Secondary coil 5m is supported on strip |99 by its leads and disposed with its central axis perpendicular to the primary 99a, 41a, as best shown in Fig. 5. Capacitor 63a is mounted on and has one terminal connected to a downturned lug on bracket I23a (Figs. 5, 6) riveted to strip |99 and connected to terminal 25a. The other terminal of capacitor 93a is connected to fixed capacitor 9Ia, also to terminal 24a by conductor I25a. The remaining terminal of capacitor 6Ia is connected by conductor I24a to capacitor 62a. Capacitor 92a is also mounted on and has one terminal connected to a lug or bracket |23a, Connected to terminal 25a.

To complete the circuit for applying local oscillations to the terminals 29a, 25a, 39, coil 69a is mounted atop ceiling 12 in alignment with oscillator tank coil 55a. Conductor I29a connects one lead of this coil to terminal 29. Conductor |240; connects the junction of the other coil 69a lead and capacitor Bla to capacitor 62a. Elements 29a, 25a, 99a, Sla, 92a, I24a, |25, |2601., 29 collectively function to apply local oscillations to the frequency converter input.

Ceramic insulating sleeves I39a, I3 Ia, I32a and |33 are employed for leading conductor 90a, the line from coil 69a to capacitors 6Ia, 52a, and conductors I26a and 9| through ceiling member 12. The upper compartment is hermetically sealed.

In Fig. ll there is shown an alternative form of circuit suitable for incorporation in the dual channel selector unit. One channel is illustrated, and it will be understood that the other channel may be generally similar, diiering in circuit di-y mensions. Circuit elements of Fig. l1 identical with Fig. 9 circuit elements have identical reference numerals andsimilar elements have major letter suiiixes. In the Fig. 11 circuit the oscillator and antenna input sections are so similar to those illustrated in Fig. 9 that further description is deemed unnecessary. Substituted for the three capacitors SIb, 921i, 93h is a single double ended fixed capacitor 63B. Oscillator voltage is taken from a tap I35B on coil 55B and introduced at the center terminal of capacitor 93B, shunted across coil SIB. This tap is also connected to plate resistor 53B for anode supply. The mounting I5 and tube shield 'I3 are grounded at |36. This alternative circuit` has the advantage that coil 99h, sleeve |322), conductor |2617, terminal 29, conductor |2419, and sleeve I3Ib are dispensed with. The main difference between the Figs. 11 and l0 circuits resides in the fact that in the Fig. l1 commercially preferable circuit, oscillator voltage is taken from tap |35 rather than from a coupling coil. Coil 5|b is tuned by a magnetic slug |31.

In Fig. 1l one position of each of switch sections I'Ia, |119, Ild, I'Ie, I'If is schematically shown. Y Switch section I1c is also dispensed with. Terminals 29, 29 are not used.

Referring now specifically to Fig. 10 the cou= plingV of the channel selector to the converter stage is shown. The cathodes of the converter tuberi Baare. grounecl'ithroughsswltchssection flfl'c. The antenna input transformer secondary .rterifminals @are viindia'ridually :coupled Lito :the Yrcon'trol -electrodes.126.an`d' 2111 throughswtchasections f I'IIZ and #I lie. Both =.terminals of .f1secondaryxl5lb Aare zatithe-y same D aC. :.potentialzasozthatonly :one .rgrd :resistor ital) need he arprovided (coupled .to grid 26;inil3ie-l'101orrgr'd -zflfiniFig. 11d. Theianodes of .f tube :i243 are -f coupled as by #terminals t4 I., |142 .to v.the fintermedia'teereduency :ampliner :input .teansformerfmm shown). @ne :filament leadffis f-grtounded: and the-.ether v-tas :well-astemninal 0) are connected to the fhigghrsideeof A.the -.-lament supply (Af) .-Shuntedfacross the individual,,inputcircuits of .tube -28are.glass.trimmer .capacitors Lili-and IM. .These A:capacitors insure .xed input canacitances .to whe-.converter circuits andfprovide for Acon- `:sistent.,Izierformance of v.the-, f: onverter `stage #all channel fselector units. These capacitors are .employed to equalize ...the-,converter input capaci- .tances -.Capacitors ...I 4.5 .and llfare ,providedffor .neutralizing v gridTp-late fcapacitances, -capacitor being .connected `lbetween .terminal v.IM n.and grid .21 and vcapacitor L45 .between terminal 1.4.2 vendend-26.

l ,Referring .now ,specically .to-Fig. .12. it 4wilhbe .seen that the converter v.tuloe .28, the sockets 355, '36 .T31 ande38 ...and tthe..channel:eelectorzfswitch IJ .are mounted-as, aA subassemblyfon a lease ,-I.59,=se- .cured to chassis.l5|. .'lhesocketsand thetulce are `arranged. -suhstantially in .fa .rectangle .with thelchannel-selector .switch .I1 .in tlaevcenter., .onder .to make .themfiring to allchannel selector units as :uniformes- `p ossilcle.

Although :the invention :is not limited to ...any .specic ,circuit .parametersmhe.iollowing paramfeter-,s have been .ioundhsatistactory Lin .one..suc .cesstulremhodimentrof the: invention '}fdual ceramic.

Capacitor (85B side) l40 msmrf; {GapaicitonGB .1151111. m.. f. on each side, dual ceramic. Capacitor 49B .25. 270J11m. f., trimmer, mica. Resistor 57B.. 390g000 ohms, Watt. Resistor 53B 8,200 ohms, watt. ,AndVltage 2200;.vo1ts.

Tank Coil 55B 2% .turna ...d-ia.A .of -'coi1 lz,

wire gauge'#l4. Primary 46B;,.47.B,148B '1% turns, v'dia. of coil 1%",

wire gauge "#14. Secondary 51B l5%:tums, dia. oi..coil 15467,

y Wire gauge #16. "nverter Stage: r

- Tubelfh. 11738.

'Gapactorsland'l L"laclK-' m. :n.f'ft'glass `triml men .Gapaoitorslfi and 146 aclLLIlm. m. fased.

*Plate Voltage '100 volts.

' E'Resstonlll :Intermediate Frequency '.TrPicture ,Carrier Channel 2 n faccordance with 4a rfeature of the present inventionfa' high-degreeofrequency stabil-ityl'of the channelselectcr 'unitsiisiprcvi'ded The effects of .humidity .on the oscillator.have.been completely eliminated by pl'acingltne entire ,oscillator in a hermetically sealed' metal :container (Figs. 1, 2), comprising an inverted metal cup |60 soldered to the upstanding annular ilange on the horizontal divider or ceiling member l2 (Fig. 3). The lower or antenna input circuit section is shielded but not sealed by a cylindrical metallic shield IBI, having one end tted over the ange o'f Etnol :ceiling :rnrember i112 .and the other and screwed lto unstanding integral :lugs i on fsb-ase 1.1); fills@-ShownfinEigs.:5rand 7,theoscillatoitankicir cuit capacitors 515m .',Bb :lare zsupported :fat 'lboth ends :.and;the1slugs @81| tand 382 :are securely :Dosi- .tioned by splitzbu`shingplocks,; in iorderto, preuent `drift-edile..tofmechanicalaimee -;C.upa; I 6,0 @has :two .integral npstanding hollow `fexteriorly ltlnzeaderl :bosseseadaptedeto :be tightlygclosedby removable interiorly threaded acaps [52, 453., to :provide ready@aceessetotheeadjustmentsfior..the magnetic slugs. The :larg-e Ltank capacitors '5ta and 25,61) .minimize-swarm-upgdrittiandnthe:frequencyfjdritt Leffects o`f;1ine voltage variations. VIIO :minimize .driftdwith :temperatura the temperature co-ref- .iicientmfithei tank-capacitors ois :chosena suchra manneraas .tmake the V*temperature co-leflcient of the. entire atankrcircuitsubstantially .zero and .the oscillator isaa'dustediat theezaverageztempera- -tnreeofrtheoscillatoresectionwwithin thezrangenf temperaturesexperiencedain operation. .Stra'ins gare .-:eqnalizedfby-zsuhiecting the channel ;fselector 'imitsitoia tempenatureonthe order of120fidegrees centigrafdef-,forsavperiodgoflaonerto'two :hoursprior '.tolnahalignment.

Coming now to a description of the onerationiof :the :.aiboveadescribed circuits :and structures,A it .will zbefassumed: thateswitch .-.H ,is @turned tof-.the vpositienesliiown.-imli'ia 10. Wave-signals1are-intercepted-bythe antenna .systemandapnlednto .terminals flied; allaandzthezantennaiinput trans- :former:primaryi4.6a,.fAlcanza. Thenprimaryptun- .ingi'is adnistedzby :capacitor: dilagandlthersecond- -ary timngns adjusted rby capacitor -;:63a, soythat Ittre antennazinputfcircuitsis azselectiveband-ipass 'circuit '-:Which voltage-:amplies :the :received Esignals and applieszthemzto :terminals 2 411,:2511 and ...the grids :#26, .21 affiche :converter stage. band-':pf.ass1cirnufu'f.- is'foptimized-ffcr the particular channel. .mrezmse @of fa: neutralized i-.triode `acon- `verter@resultsiin: a ,iavorablennputf impedance to the converter stagensothatzaireasonablefgainfis realized-intheantermatransformer. Localioscil- 'flations :o ff-xede frequency; appear;y intthe .tankf cirr-.upfbycoillsllm eiectronragnetical'lyicoupledxovtank circuit nductor A5511. ue'lhe :local ioscillations :are appliedeto 'terminals .2..4a,a25a and the grids $26, 2:1:;of itheconverterbyeoanacitons 6 ta;;'6:211,:inzbal ainced @relation ato terminal 29 y,f (for fconve'rter cathodei.

Balanceda x:oscillator :radiationinto l:the-^fantenna circutzisrminimizledvbyfbalandacouplingfbetween :secondary :coil 25m aand :primary fcoils f 46a, .14T-a, andabysthe'balancddconverterinnuticircint The met .:oscillator voltage :across secondary t 5in, ias :seen @by Mppi-mary :i4 Ga, 457.11 is substantially faero, `since-the twozsectionsrof twingtriode :2:8 farealike 4iniziali-ase .angleffzandrcapacity load, fso'that radiation' -izolta1gesaapplied to primaryzcoil i4 Ixaiare canzcelled1fbya those rappliedz to f primar-y ucoil f4?! a.

'Since felectrostatic 4fconplin'g #between Ftlfre Aprimary dla, 545m: fand itazto: therfsecondaryf'coil SfI-a is 'almost `l`elin'iinated by=m'eans xrof the velectrofstatic sshield': 52a, lonly thecelectromagnetic 'cou'- .pling eis vdeft. yGorisedirlently, sa -pushepush signal avillt'induceznonvoitageiin ,th'evsecondary since-.it fWillrnot-resirltfinfa magnetic'ield.. f

To prevent unbalanced radiation electrostatic and electromagnetic coupling between all circuits carrying oscillator voltage and the antenna is minimized. Electrostatic coupling between the oscillator and antenna wiring is prevented by locating the channel selector circuit wiring and elements, such as the antenna input transformer circuit and the oscillator circuit, within separately shielded enclosures. Fin 15 shields from each other the two oscillator circuits external to tube I8. The center partition 91 shields antenna transformer circuit 23a from the similar circuit 23h.

The hair =pin primary such as 46a, 47a is shielded yfrom the secondary, such as la, by shield 52a, consisting of tubular members |I2a, |l3a, grounded to partition 106. Additional shielding between primary and secondary circuits is provided |by placing each primary tuning trimmer such as 49aV in a'separate compartment, for eX- ample, the compartment defined by members |05, |06. Further, each primary tapping coil, such as 48a, together with the antenna leads, such as I2'l a, l22a, is mounted in a separate compartment, as' defined by walls 91, 98, 99 for example. The four-prong plug underlying the walls 96 and 98 carries only the antenna terminals 19a, |91), 20a, 20h, thereby minimizing the amount of oscillator power coupled into the antenna through electrostatic coupling. The channel selector unit is so well shielded and balanced that a preceding R. F. stage may be dispensed with, without eX- ceeding a reasonable amount of oscillator radiation.

The oscillator circuits are optimized and so stable and fixed-tuned that no Vernier tuning is required. They apply oscillations of a predetermined frequency to the input circuits of converter tube 28. In the converter stage the local oscillations and amplied received signals are heterodyned or beat together to producev resultant different-frequency intermediate-frequency signals which are then selectively amplified in the intermediate-frequency amplifiers in a manner well known to those skilled in the art.

From the foregoing description, it will be seen that the invention radically enhances convenience, service, economy and performance in television reception and the like. Convenience, because Vernier tuning is dispensed with, the operator simply turning a channel selector switch to a predetermined position or otherwise bringing into operation a specific channel selector unit, whereupon that unit strongly discriminates against-and attenuates signals in other channels but amplies received signals in the desired channel and applies such desired received signals and stable oscillations of proper frequency to the first converter stage. Strong, relatively interferencefree, intermediate-frequency signals having a stable carrier frequency are accordingly produced.

Service, because the channel selector units are easily repaired or replaced without putting out of operation other selector units and the receiver as la whole. Economy, because the consumer does not have to purchase channel selector units for all of the assigned television channels. If only one channel is available in his district, for example, he requires only one channel selector unit and need not purchase any additional units. Performance, because each channel selector unit is concerned with only one television channel and may be'designated to handle that channel with maximum gain, selectivity, sensitivity, eiciency, fidelity and stability. The invention departs radically from conventional televisionV practice 16 and provides for truly tailored televisionV reception.

While there has been shown and described what is yat present considered to be the preferred embodiment of the present invention, it will be obvious to those skilled in the art that various changes, modifications and substitutions of equivalents may be made therein without departing from the true scope of the invention, and it is, accordingly, intended in the appended claim fairly and properly to cover all such changes, modifications and substitutions as fall within the true scope of the invention.

Having fully described my invention, I claim:

A channel selector unit for insertion between the antenna circuit and the first frequency converter stage of a superheterodyne television receiver, of the type including wave intercepting means having output contacts and a frequency converter having input contacts and a potential supply having an output contact, comprising a mounting member having contacts complementary tothe aforementioned contacts, a fixedtuned antenna input circuit carried by said member having an input adapted to be coupled through the first-mentioned contacts and their complementary contacts to said wave intercepting means, said antenna input circuit having an output adapted to be coupled through the second-mentioned contacts and their complementary contacts to said frequency converter, a fixedtuned local oscillator having an output adapted to be coupled through the last-mentioned contaots to said frequency converter and an electrode adapted to be coupled through the third-mentioned contact and its complementary contact to said supply, said antenna input circuit being optimized to pass intercepted carrier signals within a distinct desired channel and said oscillator being optimized to apply to said converter oscillations of a frequency appropriate to heterodyne said received signals to a predetermined intermediate frequency, whereby insertion and switching of said unit into said receiver conditions said receiver to select carrier wave signals within a single desired channel.

JOHN DRYSDALE REID.

REFERENCES CITED The following references are of record in the le of this patent:

UNITED STATES PATENTS Number Name Date 1,612,952 Stevenson Jan. 4, 1927 1,666,505 Peterson Apr. 17, 1928 1,816,461 Baird July 28, 1931 1,851,354 Flewelling Mar. 29, 1932 2,029,461 Brush Feb. 4, 1936 2,062,379 Silver Dec. 1, 1936 2,173,898 Conron Sept. 26,'1939 2,285,372 Strutt June 2, 1942 2,383,322 Koch Aug. 21, 1945 2,421,676 Beard June 3, 1947 2,440,308 Storck Apr. 27, 1948 OTHER REFERENCES Article in Radiocraft, January 1939, pages 40o-401, and 431. Y 

